DE425973C - Device for determining distance by means of reflected pulses - Google Patents

Description

Device for determining distance by means of reflected pulses. The invention relates to a device for carrying out the method of measurement the distance traveled by a sound emitted or emitted at a certain point in time. emitted and after a certain period of time as a reflected sound pulse is taken up again, so that from the between emission and reception of the sound lying time interval the distance of the reflection point in a known manner which can be found.

The device used for this is basically known per se and designed so that the display device of the receiving device for recording of the reflected pulses are ineffective during the transmission of the primary transmission pulses is done, while conversely the transmitter is at rest as long as the reflected Impulse is observed. The known devices of this type meet the requirements Requirements are not complete, as the distances to be measured have a certain maximum must not exceed, because otherwise the reading of the numerical values on (ler - \ Iessskala the display device made difficult and consequently the measurement ung; @: au is. the Invention eliminates this deficiency, lui-1 it consists in such a training the device for the transmission and reception of the sound, that any length of travel measured with approximately the same percentage accuracy of the reading of the measured values can be achieved by gradually adjusting the device to different specific measuring ranges set «- can be earthed, e.g. B. to o to iooo in, 100o to 200o in, 200o to 300o 111 tisw. or the other way around. The invention thus senses a separate setting on large and small units of measurement and a corresponding transmission of the primary Sound impulses by setting the apparatus to a certain measurement range from Z. B. 1o00 111, 2000 111, 3000 111 etc. or vice versa, and within one such area allows searching for the final result. Is the The distance you are looking for is not in your first streamed thousands range, so must the apparatus is set to other thousand ranges "- until finally in a certain position of the display device, e.g. B. at 3125 in, which is reflected Pulse is displayed. According to the invention, two are used for reading the measured values Measuring scales provided, one for the thousand ranges and one for the range of Hundreds, tens and ones together.

In the drawing, the system according to the invention is ini scheme an embodiment shown, and here the invention is for example realized on an apparatus for measuring the depth of the sea.

I mean an underwater sound transmitter, 2 an underwater sound absorber, 3 and 5 rotating disks, which are set in motion by a motor 0 are in the direction of rotation indicated by arrows. 7 and `are adjustable by hand Support disks for rotatably mounted contact levers 9 or 1o, which are used to switch from Serve electrical circuits and finite the support disks can be moved. The disks 7 and 8 each work together with a measuring scale i i or 12 and are provided with a pointer 13 or 14 for this purpose. The drawn system is located in zero position and rest position.

The transmitter i of the usual type is powered by an alternating current machine 15 operated by the frequency of the desired signal tone, its circuit on a Contact relay 16 is controlled via the contacts 17, 18, so that according to the Closing these contacts excites the transmitter 1 and emits the sound pulses he follows. The relay 16 is connected to a direct current battery 1c) and its line connections extend over a contact lever 20 controllable by Jcr disk 8 and one of the disc .4. controllable K-ontaktliebel 21. Parallel to the current path via the contact lever 2o and 21 there is another connection option for closing the circuit of the relay 16, via a contact lever 22 and a second contact on the lever 2a in such a way, in the event of the closure of one line connection the other is interrupted.

The receiving device consists of the receiver 2 and a display device 23, e.g. B. a remote receiver, which by means of a transformer 24 with the receiver 2 is inductively coupled. The primary winding 25 of the transformer is in series connected finit clerri receiver 2 and the secondary winding 26 in series with the Handset 23. The secondary circuit of the transformer 24 has two of the lever 9 of the Disc 7 and (learn lever i o of disc 8 and another Hebe127 controlled Short-circuit connections that are canceled in certain positions of the discs 3 and 5 be, in the rest of the time ater short-circuit the listener 23, so that this during the transmission of the sound by means of the transmitter i is ineffective.

The rotating disks 3, q. and 5 are so connected to the motor 6, that the disc 3 rotates faster by means of a transmission gear 28, 29 than the disks and 5. The latter have the same number of revolutions.

As can be seen, the disc 3 has on its circumference one with the Lever 9 cooperating nose 3o, the disc .I several equidistant from one another arranged lases 31 acting on the lever 21, one of which (31 ') is larger is than the others and acts only on the lever 22, which is from the disc .I has a slightly larger distance than the lever 21. The disc 5 has a single one Lug 32 for the lever 1o. The rotational speed of the disc 3 against that of the Discs 4. and 5 is dimensioned so that when the disc is rotated @. from a nose 31 to the other one full turn, while the nose 32 of the Disk 5, cla has the same speed as 4., is in the same 'Time moved by the mutual distance between two noses 31 of the disc 4. The nose 32 of the disk is made so wide that it covers an angle, the your between two vases 31 of the disk .4 is the same.

The manually adjustable discs; and 8 sit loosely on theirs Axes and can with the help of the pointers 13 and 14 and the associated circular scales i i and 12 can be set in certain positions to which the @c «-cilige The position of the levers 9 and ro corresponds to the disks 3 and 5. The scale 1i is in Depth meter divided from i to rooo and the speed of the disc 3, taking into account the running time of the sound, dimensioned so that the pointer 13 with the setting of the apparatus described below, the removal of the Shows the sound reflection point in meters. The scale r2 is according to the number the lugs 31 of the disc d. provided with 6, sections, which in whole thousands, from rooo to 6ooo in, are calibrated. Opposite your pointer is located on the Scheike 8 a nose 33, which in the zero position of the disc 8, d. H. in the middle position of the pointer 1.1., between o and rooo opposite the first sector of the scale 12 the inevitably interconnected levers 2o and 2; still moved away in all the rest Positions of the disc 8 but releases this lever.

The mode of operation of the device described is as follows: It is assumed that: the supplement is in the state shown in the drawing or 22, namely the one larger nose 3 r 'of the disk d. on the lever 22. The nose 33 of the disk 8 is in engagement finitely with the levers 20, 27. If the drive motor 6 is now switched on, the disks 3 d. and 5 in the direction indicated by arrows in continuous rotation, whereby first the lever 21 is thrown and its contact 35 is closed for a short period. (Although the lever 22 is also thrown and the contact 36 is closed; This contact closure is initially irrelevant, since the contact 37 of the lever 2o is still open. The closure of the contact 35 of the lever 2r results in the switching on and excitation of the relay 16, its circuit via the following path runs: negative pole of battery ic), winding (les relay i6, line 38, lever 20, contact 39, line .4o, lever 21, contact 35, line di and back to the positive pole of battery i g. The relay 16 attracts its armature and thus switches on the transmitter i for the duration of the closing of the contact 35 of the lever 21, whereby the first - # egg pulse is sent out. Since, as the figure shows, at this moment the vase 30 of 3 had already left the cam of the lever 9, there is a short circuit for 23. It is assumed that the sound travels to the reflecting surface and back as long as the Disk 3 needs to go around once. One then sees that the axis 3o is just pushing the lever 9 away when the sound comes back and hits the receiver 2. Under the given conditions, the observer can now perceive the reflected pulse arriving at the receiver 2 in his receiver 33. The process described is repeated with each subsequent one through the noses 31 of the disk d. induced closure of the contact 35. If the zti measuring distance is now less than iooo in hzw. is the reflection - @@: and for the primary sound pulse at a distance of z. B. 25o m from the observation point where the apparatus is set up, you will not be able to hear the reflected pulse with a full rotation of the disk 3, since the opening of the contact 42 does not take place at the moment of arrival of the reflected pulse. In order to bring about this state, one must set the hand disk 7, which is provided with the pointer 13, and look for the particular degree of distance on the scale ir. Here are finitely the disk 7 of the lever 9 and its contact .42 adjusted against the disk 3 against the direction of rotation of the disk 3, until the observer in 23 hears the reflected pulse. In the example of a depth of 25o m, this would be the case if g tun 18o ° is adjusted against the direction of rotation of 3. There the value 500 m is on scale ii.

As can be seen, the measures described above are sufficient from clearly measuring distances up to rooo m. Because beyond that, not it is easy to determine which transmission pulse the recorded reflected Momentum, in the higher thousands every measurement of i i is with respect to the thousands ambiguous, even if it is always correct about the hundreds, Tens and ones.

For the purpose of finding the thousands of meters one has to look apart from the just described measuring device of the disks 5, 8 and the scale 12 operate.

Assume that a distance between rooo and 2oo m is to be measured.

In the process just described, the disk 8 with its pointer was roughly in the first sector of the scale 12, which indicates the distance from 0 to 100 m. The disk 8 is now set with its pointer approximately in the area of the scale 12, which corresponds to the measurements from 10,000 to 2,000 m. So this is the next sector of the scale following clockwise. With this setting of the disk 8, its nose 33 is moved out of the area of the levers 20, 27, the lever 20 opening the contact 39 , but closing the contact 37 and the lever 27 closing the contact 43. The opening of the contact 39 has the consequence that the current path of the relay 16 running over the lines 38, 40, 41 is permanently interrupted and is no longer interrupted at the contact 35 of the lever 21 1: each time a nose 31, 3i 'of the disk 4 passes by can be closed. The closing of the contact 4.3, on the other hand, brings about the production of a short circuit to the remote receiver 23 via a different route, as is readily apparent from the drawing. This short circuit can be interrupted by the lever io, which when the vase 32 of the disk 5 moves past its contact 4.4. opens. As a result of the appropriately dimensioned circumferential length of the nose 32 of the disk 5, the opening of the contact 4.4 takes place during one full revolution of the disk 3. Since the closure of the contact 36 of the lever 22 has now become effective through the described permanent closure of the contact 37 of the lever 2o, so is only turned on every day, the disk. the relay 16 turned on und_erret, "namely ü #er -Töigenden Stromweg - Mlinuspol the battery i9, winding of the relay 16, line 38, lever 20, contact 37, line 45, lever 22, contact 36, line 46 and back to Positive pole of battery 19. Although the short circuit at 10, 44 has now been removed, there is still no possibility of hearing the reflected pulse in 23, since 4 @ a is still closed at 9. The possibility of listening only exists when through the nose 30 of the disk 3, the contact 4.2 of the first short-circuit device is also opened and this opening occurs by setting the lever 9 by means of the hand disk 7, as described above .2 of the lever 9 in the remote receiver 23 can perceive the reflecting impulse if the distance to be measured lies in the measuring range from 100 to 200 m. For higher thousands, the disc 8 with pointer 14. a Set to one of the following measuring ranges on scale 12.

In the case of completely unknown depths, the measurement takes place in such a way that an attempt is first made on i i to obtain a reflecting pulse. Amounts to If the depth is up to 500 m, this is successful, otherwise 8 has to be adjusted from 100 to 2,000 and each time the attempt by i i be repeated until the reflected pulse appears. In general, one is well informed about the thousands in question so that the procedure turns out to be _simpler than it would appear afterwards.

Claims (4)

PATENT CLAIMS: i. Device for determining distance by means of reflected impulses (sound), in which the measurement is carried out in that an Etnpfansvorrichtuna only in @u men ic: c es i Intre _en s des ertle * r.t, Jmss-wrl # "# am emacht, thereby marked, because there is a uniform measurement accuracy for any distance (Depth) the measuring device has two adjustment devices (7, ii and 8, 12), one of which is used to determine the depth in large units, the other to It is used to determine the depth in small units. 2. Device according to claim i, characterized in that with each of the two adjustment devices a device to ineffectively the receiving device is connected in such a way that the latter is only ready to take pictures when both adjustment devices are at the correct distance are set. 3. Device according to claim i and 2, characterized in that that the device indicating the arrival of the reflected pulse (e.g. Telephone) via the contact devices (9 and 1o) is short-circuited, which corresponds to the switching position of contact devices (2o, 2i, 22) to close electrical circuits for the transmission of the primary pulse at depths of large or small measuring units and with the correct setting of the measuring device can be made ineffective during the search process. 4. Device according to claim i to 3, characterized in that the transmission contacts (35, 36) and short-circuit contacts (42, 44) are controlled by rotating devices (-. Or 3 or 5), their speed of rotation is mutually regulated in such a way that the abolition of the short-circuit £ iir depths takes place so much more often in small units than with a full revolution the one rotation device (4) the transmitting contact (35) is closed while for depths in large units, the short-circuit with each full revolution the rotating device (4.) is canceled once.